Global ETD Search

281	A contribution to photonic MEMS : study of optical resonators and interferometers based on all-silicon Bragg reflectors Malak Karam, Maurine 17 November 2011 (has links) (PDF) This research work has been conducted to introduce a novel class of Fabry-Perot (FP) resonators : curved FP cavity based on coating-free Bragg mirrors of cylindrical shape, obtained by silicon micromachining. Another specificity is the rather large cavity lengths (L>200 µm) combined with high quality factor Q (up to 104), for the purpose of applications requiring cavity enhanced absorption spectroscopy, in which the product Q.L is a figure of merit. In this contest, the basic architecture has been modeled analytically to know the high order transverse modes supported by such cavities. Hence, the experimental conditions which lead to preferential excitation (or rejection) of these modes have been tested experimentally leading to the validation of our theoretical model and to a better understanding of the cavity behaviour. A second architecture, based on the curved FP together with a fiber rod lens has been developed for the purpose of providing stable designs. It was also modeled, fabricated and characterized leading to the expected performance improvements. On another side, a highlight on one of the potential applications that we identified for the curved cavities is presented by inserting the cavity into an electro-mechanical system. It consists of exciting and measuring tiny vibration through opto-mechanical coupling in a MEMS mechanical resonator embedding an FP cavity.Finally, as a complement to our study on resonators, we started exploring applications of optical interferometers based on similar micromachined silicon Bragg mirrors. For this purpose, an optical measurement microsystem was designed, fabricated and characterized ; it consists of an optical probe for surface profilometry in confined environments, based on an all-silicon Michelson interferometer [SPI:OTHER] Engineering Sciences/Other Optical MEMS Vibration measurements Interferometers Bragg mirror Michelson interferometer Curved Fabry-Perot cavity
282	The Advanced Virgo Gravitational wave detector : Study of the optical design and development of the mirrors Bonnand, Romain 27 September 2012 (has links) (PDF) Gravitational waves have been predicted by Einstein in his General Relativity theory. Theyare perturbation of the space-time metric and we try to reveal them by laser interferometry. More precisely,gravitational wave detectors are km long Michelson interferometers combined with Fabry-Perot cavities.The network of first generation detectors (Virgo, LIGO, GEO) did not permit a direct detection afterseveral observational runs in coincidence at the nominal sensitivity. A second generation of detectors is inpreparation with in particular the European project Advanced Virgo. This detector should have a sensitivityincreased by an order of magnitude compared to Virgo. The interferometer mirrors play a crucial role inthe Advanced Virgo sensitivity as it is limited by the mirror thermal noise in the mid-frequency regionand by the amount of photons collected in the interferometer cavities at high frequencies. The high powercirculating in the Fabry-Perot cavities induces important thermal lensing effect. This thesis is interestedfirst in the thermal lensing effect in the interferometer for different optical configurations. Then we areinterested in the mirrors composing the Fabry-Perot arm cavity from the calculation of the requirements interms of flatness to the realization of the mirrors flatness and its measurement. The mirror flatness shouldbe sub-nanometric in order to limit the optical losses in the Fabry-Perot cavities to reduce the effect of theshot noise and of the diffused light. We will see the correction of the substrates flatness by the so-calledcorrective coating technique. Finally, we study the uniformity of the dielectric multilayer coating depositionnecessary to obtained high-reflective mirrors. We study in particular the planetary motion of the substratesin the coating machine. Gravitational waves Interferometry Advanced Virgo Thin films Fabry-Perot cavity Corrective coating Metrology
283	Multiplexed optical fibre sensors for civil engineering applications Childs, Paul, Electrical Engineering & Telecommunications, Faculty of Engineering, UNSW January 2007 (has links) Fibre-optic sensors have been the focus of a lot of research, but their associated high cost has stifled their transferral from the laboratory to real world applications. This thesis addresses the issue of multiplexing, a technology that would lower the cost per unit sensor of a sensor system dramatically. An overview of the current state of research of, and the principles behind, multiplexed sensor networks is given. A new scheme of multiplexing, designated WDM, is developed and implemented for a fibre Bragg grating (FBG) optical fibre sensor network. Using harmonic analysis, multiplexing is performed in the domain dual to that of the wavelength domain of a sensor. This scheme for multiplexing is compatible with the most commonly used existing schemes of WDM and TDM and thus offers an expansion over, and a resultant cost decrease from, the sensor systems currently in use. This research covered a theoretical development of the scheme, a proof of principle, simulated and experimental analysis of the performance of the multiplexed system, investigation into sensor design requirements and related issues, fabrication of the sensors according to the requirements of the scheme and the successful multiplexing of eight devices (thus offering an eightfold increase over current network capacities) using this scheme. Extensions of this scheme to other fibre sensors such as Long Period Gratings (LPGs) and blazed gratings were also investigated. Two LPGs having a moir?? structure were successfully multiplexed and it was shown that a blazed Fabry Perot grating could be used as a tuneable dual strain/refractive index sensor. In performing these tests, it was discovered that moir?? LPGs exhibited a unique thermal switching behaviour, hereto unseen. Finally the application of fibre sensors to the civil engineering field was investigated. The skill of embedding optical fibre in concrete was painstakingly developed and the thermal properties of concrete were investigated using these sensors. Field tests for the structural health monitoring of a road bridge made from a novel concrete material were performed. The phenomenon of shrinkage, creep and cracking in concrete was investigated showing the potential for optical fibre sensors to be used as a viable research tool for the civil engineer. Optical fibre sensors. Wavelength-frequency multiplexing. WDM. FBGs. Moir?? LPGs. Blazed Fabry-Perot gratings. Testing of concrete. Optical fibre detectors. Fiber optics.
284	Dynamics of the thermosphere over Mawson, Antarctica / by P. Wardill Wardill, P (Paul) January 1988 (has links) Bibliography: leaves 140-151 / 151, [2] leaves : ill ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Mawson Institute, 1989 551.514 20 Thermosphere. Atmosphere, Upper Antarctic regions. Winds aloft Speed Antarctic regions.
285	Plasmonic-based Label-free Detection and Imaging of Molecules January 2011 (has links) abstract: Obtaining local electrochemical (EC) information is extremely important for understanding basic surface reactions, and for many applications. Scanning electrochemical microscopy (SECM) can obtain local EC information by scanning a microelectrode across the surface. Although powerful, SECM is slow, the scanning microelectrode may perturb reaction and the measured signal decreases with the size of microelectrode. This thesis demonstrates a new imaging technique based on a principle that is completely different from the conventional EC detection technologies. The technique, referred to as plasmonic-based electrochemical imaging (PECI), images local EC current (both faradaic and non-faradaic) without using a scanning microelectrode. Because PECI response is an optical signal originated from surface plasmon resonance (SPR), PECI is fast and non-invasive and its signal is proportional to incident light intensity, thus does not decrease with the area of interest. A complete theory is developed in this thesis work to describe the relationship between EC current and PECI signal. EC current imaging at various fixed potentials and local cyclic voltammetry methods are developed and demonstrated with real samples. Fast imaging rate (up to 100,000 frames per second) with 0.2×3µm spatial resolution and 0.3 pA detection limit have been achieved. Several PECI applications have been developed to demonstrate the unique strengths of the new imaging technology. For example, trace particles in fingerprint is detected by PECI, a capability that cannot be achieved with the conventional EC technologies. Another example is PECI imaging of EC reaction and interfacial impedance of graphene of different thicknesses. In addition, local square wave voltammetry capability is demonstrated and applied to study local catalytic current of platinum nanoparticle microarray. This thesis also describes a related but different research project that develops a new method to measure surface charge densities of SPR sensor chips, and micro- and nano-particles. A third project of this thesis is to develop a method to expand the conventional SPR detection and imaging technology by including a waveguide mode. This innovation creates a sensitive detection of bulk index of refraction, which overcomes the limitation that the conventional SPR can probe only changes near the sensor surface within ~200 nm. / Dissertation/Thesis / Video for Figure 3.2 C to H / Video for Figure 3.5 / Video for Figure 5.5 / Video for Figure 6.7 / Video for Figure 6.11 / Ph.D. Electrical Engineering 2011 Electrical Engineering Analytical Chemistry Charge detection of single particle Fabry-Perot microscope graphene electrochemical imaging Nanoparticle catalysis reaction Plasmonic-based Electrochemical Imaging Surface plasmon resonance
286	Strong light-molecule coupling : routes to new hybrid materials / Couplage fort lumière-matière et les conséquences pour les matériaux moléculaires Wang, Shaojun 11 September 2015 (has links) Durant les 15 dernières années, le couplage fort lumière-matière avec des matériaux organiques a attiré un intérêt croissant, notamment à cause des valeurs extrêmes que peut atteindre l'écart énergétique entre les modes couplés dans ces systèmes. Ces modes couplés sont des hybrides lumière-matière, aussi appelés états polaritons et notés habituellement P+ et P-. La valeur de I' écart énergétique entre les modes couplés, également appelé énergie de Rabi-splitting, est provoqué par une transition efficace de dipôle moments entre des molécules et aussi par des cavités ou des plasmons en surface de petits volumes en mode de micro-Fabry-Pérot métalliques (FP) qui sont utilisés dans ces études. Rabi-splittings - 1eV représente souvent une fraction importante de l'énergie de transition électronique, dans ce cas, le système est appelé dans le régime de couplage ultra-forte. Dans ce régime, la physico-chimie des molécules ou des propriétés des matériaux du système couplé peuvent être modifié. En effet, d'effet a déjà été montré sur les voies de relaxation dans le système couplé, les taux de réactions photochimiques, le travail d'extraction et de la conductivité des semi-conducteurs organiques dans l'obscurité, entre autres choses. Une étude récente a pu montrer que l'énergie de l'état non-excité dans une étude thermodynamique peut également être décalée dans le régime de couplage ultra-fort. De plus, le couplage fort ne se limite pas à des transitions électroniques, mais peut aussi être utilisé pour perturber les vibrations de l'état non-excité de molécules dans la région infrarouge. Tous ces résultats montrent que le couplage fort en lumière-molécule a beaucoup de potentiel pour le matériel et la science moléculaire et mérite donc une étude plus approfondie. / Over the past 15 years, light-matter strong coupling involving organic materials has been of increasing interest due to the very large energy splitting such systems exhibit between the two hybrid light-matter states, also known as the polaritonic states typically denoted P+ and P-. The large energy splitting, so-called Rabi splitting, is the result of the high transition dipole moments of the molecules and the small mode volumes of micro-metallic Fabry-Pérot (FP) cavities or surface plasmons used in these studies. Rabi-splittings -1 eV have been observed, often representing a significant fraction of the electronic transition energy in which case the system is said to be in the ultra-strong coupling regime. ln this regime the physical chemistry of molecules or the properties of materials of the coupied system should be modified. lndeed, it has already been shown to affect the relaxation pathways in the coupled system, the rates of photochemical reactions, thework-function and conductivity of organic-semiconductors in the dark, among other things. A recent thermodynamic study demonstrated that the ground state energy can also be shifted in theultra-strong coupling regime. Moreover, the strong coupling is not limited to electronic transitions, but also can be used to perturb the ground-state vibrations of molecules in the infrared region. Ali these results suggest that light-molecule strong coupling has much potential for material and molecular science and therefore merits further study. Couplage fort Matériaux moléculaires Plasmon de surface Strong coupling Polaritonic states Rabi splitting Fabry-Pérot cavity Surface plasmon Organic molecule materials Ground state shift Dynamics 547.1
287	Stacked Dual Narrowband Organic Near-Infrared Photodetectors Wang, Yazhong January 2017 (has links) Compared with the detector devices made of inorganic semiconductors, organic photodetectors are granted with additional strengths, such as flexibility, high scalability and bio-compatibility. However, in the family of organic optoelectronic devices, the detectors that are capable of detecting photons at two or multiple specific wavelengths are still missing. Such photodetectors are highly interesting because they could identify the target objects or materials much more precisely by detecting the reflected, transmitted or emitted photons at two or multiple characteristic wavelengths. In this thesis project, the optical simulations using Transfer Matrix Method (TMM) were performed on the organic devices to achieve the dual wavelength narrowband detection in the near-infrared (NIR) spectral range of 700 ~ 1100 nm. The devices use the fact that, at the interface of the blended organic electron donating and accepting materials, the charge-transfer (CT) states with the transition energies that are lower than the optical gap of the neat materials are formed. Combined with a Fabry-Perot resonant cavity, the CT absorption can be dramatically enhanced at certain wavelengths. The simulation results show that the two detection wavelengths can be tuned independently from 650 to 1100 nm. The spectral resolution (full with at half maximum - FWHM) of the detection bands varies between 10 and 30 nm. The simulated external quantum efficiency (EQE) is ~35% at 700 nm and ~10% at 1000 nm, respectively. A possible application of such photodetectors is for example moisture detection, where two of the characteristic absorption peaks of water are located at around 750 and 960 nm. By optimizing the thickness of the two photo-absorbing layers in a tandem device structure, the detection bands can be tuned to match with those two wavelengths for simultaneous and precise detection. Near-infrared photodetectors CT states Fabry-Perot resonant cavity resonant cavity enhancement tunability full width at half maximum Materials Engineering Materialteknik Physical Sciences Fysik
288	[en] METALLIC NANOPARTICLES SYNTHESIS AND FABRY-PEROT CAVITY IN FIBERS FOR OPTICAL SENSING APPLICATIONS / [pt] SÍNTESE DE NANOPARTÍCULAS METÁLICAS E CAVIDADE FABRY-PEROT EM FIBRAS PARA APLICAÇÕES EM SENSORIAMENTO ÓPTICO LEONARDO DE FARIAS ARAUJO 23 December 2016 (has links) [pt] Nanopartículas metálicas apresentam um pico no espectro de absorção devido ao efeito de LSPR (Localized Surface Plasmon Resonance – Ressonância de Plasmon de Superfície Localizado). A posição espectral do pico depende da forma, do tamanho, do material das nanopartículas e do índice de refração do meio em que se encontra. Conhecendo como a posição espectral deste pico varia de acordo com o índice de refração externo, pode-se utilizar, em princípio, estas nanopartículas como elemento sensor para medir a refração de líquidos e gases. Um sensor de índice de refração foi desenvolvido fabricando-se nanopartículas metálicas na extremidade de uma fibra óptica. Estas nanopartículas foram fabricadas a partir de um filme de ouro evaporado na extremidade de uma fibra óptica que depois foi aquecida. As nanopartículas assim formadas possuem uma distribuição não homogênea de forma e tamanho. De forma a se obter um maior controle do tamanho e da forma das nanopartículas metálicas fabricadas para o desenvolvimento de um sensor óptico com maior controle dos parâmetros, foi investigada nesta dissertação a formação de nanopartículas de prata por síntese química. Diferentes processos para a síntese foram investigados. As nanopartículas de prata localizadas na extremidade da fibra óptica foram caracterizadas quanto à resposta do sinal de LSPR quando as nanopartículas estavam em contato com meios com diferentes índices de refração. Visando ainda a investigação de sistemas de fibras ópticas com aplicação em sensoriamento, foi realizada uma simulação da deformação de cavidades elípticas formadas no interior de fibras ópticas quando estas estão sujeitas à aplicação de uma tensão longitudinal da fibra. Este tipo de cavidade pode ser usada como sensor de deformação devido à interferência das múltiplas reflexões no interior da cavidade. / [en] Metallic nanoparticles show a peak in the absorption spectrum due to the Localized Surface Plasmon Resonance (LSPR) effect. The position of this peak depends on the shape, size and the type of the nanoparticles as well as on the refractive index of the surrounding media. From the dependence of the position of the peak with the external refractive index, it is possible to use these nanoparticles as a sensor element to measure the refractive index of liquids and gas. A refractive index sensor was developed with nanoparticles deposited at the end face of an optical fiber. These nanoparticles, fabricated from a heated gold film deposited at the end face of the fiber, have a non homogenous distribution of size and form. In order to obtain a better control of the size and form of the fabricated metallic nanoparticles, aiming the development of an optical sensor with control of the involved parameters, it was investigated in this work the formation of silver nanoparticles by chemical synthesis. Furthermore, extending the investigation of fiber optics systems with applications on sensing, it was performed a simulation of the deformation of elliptical air cavities, formed in the interior of optical fibers, under the effect of longitudinal stress along the fiber. This type of system can be used as a deformation sensor due to the multiple interference reflections in the interior of the cavity. [pt] FIBRA OPTICA [en] OPTIC FIBER [pt] INDICE DE REFRACAO [en] REFRACTION INDEX [pt] NANOPARTICULAS DE PRATA [pt] CAVIDADE FABRY PEROT [pt] LSPR
289	Towards a squeezing-enhanced atomic clock on a chip / Vers une horloge atomique améliorée par intrication sur une puce Ott, Konstantin 30 September 2016 (has links) L’objet de cette thèse de doctorat est la conception et la construction d’une horloge atomique réalisée sur un microcircuit à atomes (TACC) et améliorée par l’intrication. L’élément principal de cette nouvelle expérience est un micro-résonateur Fabry Pérot qui permet la génération d’états de spin comprimés de l'ensemble atomique grâce aux interactions entre la lumière et les atomes. Il a déjà été montré que ces états peuvent améliorer les performances métrologiques des horloges atomiques. Cependant, les expériences ayant permis cette démonstration de principe n'ont pas encore atteint un niveau de précision présentant un intérêt métrologique. C’est précisément l'objectif de la nouvelle configuration expérimentale que nous proposons ici. Afin de conserver la compacité et la stabilité de notre installation, nous avons choisi d’utiliser une cavité Fabry-Pérot fibrée (fibered Fabry-Pérot, FFP) comme résonateur optique, dans lequel les miroirs du résonateur sont réalisés sur la pointe de fibres optiques. Pour répondre aux exigences de notre expérience, une nouvelle génération de résonateurs FFP a été développée au cours de cette thèse, les plus longs réalisés à ce jour. A cette fin, nous avons développé une procédure d’ablation par tirs multiples à l'aide d'un laser CO$_2$ focalisé, qui permet la mise en forme des surfaces de silice fondue avec une précision et une polyvalence sans précédent.L'intégration du résonateur optique au dispositif expérimental TACC nécessite une conception nouvelle du microcircuit à atomes, qui doit permettre le transport du nuage atomique jusqu’au résonateur. Nous présenterons donc la conception et la fabrication de ce microcircuit à atomes. / This thesis describes the conception and construction of an “entanglement-enhanced” trapped atom clock on an atom chip (TACC). The key feature of this new experiment is the integration of two optical Fabry-Pérot micro resonators which enable generation of spin-squeezed states of the atomic ensemble via atom-light interactions and non-destructive detection of the atomic state. It has been shown before that spin-squeezed states can enhance the metrological performance of atomic clocks, but existing proof-of-principle experiments have not yet reached a metrologically relevant level of precision. This is the first goal of the new setup. To retain the compactness and stability of our setup, we chose the optical resonator to be a fiber Fabry-Pérot (FFP) resonator where the resonator mirrors are realized on the tip of optical fibers. To meet the requirements of our experiment, a new generation of FFP resonators was developed in the context of this thesis, demonstrating the longest FFP resonators to date. For this purpose, we developed a “dot milling” procedure using a focused CO2-laser that allows shaping of fused silica surfaces with unprecedented precision and versatility. Incorporating optical resonators in the TACC system requires a new atom chip design, allowing transportation of the atom cloud into the resonator. We present the design and the fabrication of this atom chip. The completed setup will enable investigations of the interplay of spin-dynamics in presence of light mediated correlations and spin-squeezing at a metrologically relevant stability level of $10^{-13}$ at 1 s. Résonateur fibré Micro-Résonateur Horloge atomique État de spin comprimé Métrologie quantique Microcircuit à atomes Fiber Fabry-Pérot resonator Atomic clock Micro resonator 530
290	Erweitern eines Gentoo-Linux mit RTAI, LabVIEW und Comedi als digitaler Regler Jäger, Markus 12 February 2018 (has links) Der Einsatz von Computern, zur unterstützenden Durchführung physikalischer Experimente, gewinnt immer mehr an Bedeutung. Computer, unter anderem auch Personal Computer (kurz PC), können durch ihre heutige Leistungsfähigkeit, immer mehr nützliche Funktionen während eines physikalischen Experimentes übernehmen. Diese Arbeit beschäftigt sich mit dem Vorbereiten eines solchen PC, welcher für die Umsetzung einer Regelschaltung für ein physikalisches Experiment genutzt werden kann. Dazu werden Gentoo-Linux, RTAI, Scilab/Scicos und Comedi verwendet. Besonderer Schwerpunkt der Arbeit ist dabei die Regelung in Echtzeit auszuführen. Im Verlauf der Arbeit werden Hardware- sowie Software-Ansprüche und deren Anpassungen besprochen, so dass alle Voraussetzungen des Experiment-PC, zur Umsetzung eines zuverlässigen Regelprozesses, erfüllt werden. Aus Gründen, welche in dieser Arbeit erläutert werden, wurde der Experiment-PC mit der Open-Source Linux-Distribution namens Gentoo ausgestattet. Zusätzlich verfügt der Experiment-PC über eine Mess- und Steuerkarte, welche es dem Experiment-PC erlaubt Signale aus dem Experiment aufzunehmen und eine entsprechende Regelung, durch die Ausgabe von Signalen, vorzunehmen. info:eu-repo/classification/ddc/000 ddc:000

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